1 2910 128 GENE EXPRESSION PROFILING OF EPIGENETIC CHROMATIN MODIFICATION ENZYMES AND HISTONE MARKS BY CIGARETTE SMOKE: IMPLICATIONS FOR COPD AND LUNG CANCER. CHROMATIN-MODIFYING ENZYMES MEDIATE DNA METHYLATION AND HISTONE MODIFICATIONS ON RECRUITMENT TO SPECIFIC TARGET GENE LOCI IN RESPONSE TO VARIOUS STIMULI. THE KEY ENZYMES THAT REGULATE CHROMATIN ACCESSIBILITY FOR MAINTENANCE OF MODIFICATIONS IN DNA AND HISTONES, AND FOR MODULATION OF GENE EXPRESSION PATTERNS IN RESPONSE TO CIGARETTE SMOKE (CS), ARE NOT KNOWN. WE HYPOTHESIZE THAT CS EXPOSURE ALTERS THE GENE EXPRESSION PATTERNS OF CHROMATIN-MODIFYING ENZYMES, WHICH THEN AFFECTS MULTIPLE DOWNSTREAM PATHWAYS INVOLVED IN THE RESPONSE TO CS. WE HAVE, THEREFORE, ANALYZED CHROMATIN-MODIFYING ENZYME PROFILES AND VALIDATED BY QUANTITATIVE REAL-TIME PCR (QPCR). WE ALSO PERFORMED IMMUNOBLOT ANALYSIS OF TARGETED HISTONE MARKS IN C57BL/6J MICE EXPOSED TO ACUTE AND SUBCHRONIC CS, AND OF LUNGS FROM NONSMOKERS, SMOKERS, AND PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). WE FOUND A SIGNIFICANT INCREASE IN EXPRESSION OF SEVERAL CHROMATIN MODIFICATION ENZYMES, INCLUDING DNA METHYLTRANSFERASES, HISTONE ACETYLTRANSFERASES, HISTONE METHYLTRANSFERASES, AND SET DOMAIN PROTEINS, HISTONE KINASES, AND UBIQUITINASES. OUR QPCR VALIDATION DATA REVEALED A SIGNIFICANT DOWNREGULATION OF DNMT1, DNMT3A, DNMT3B, HDAC2, HDAC4, HAT1, PRMT1, AND AURKB WE IDENTIFIED TARGETED CHROMATIN HISTONE MARKS (H3K56AC AND H4K12AC), WHICH ARE INDUCED BY CS. THUS CS-INDUCED GENOTOXIC STRESS DIFFERENTIALLY AFFECTS THE EXPRESSION OF EPIGENETIC MODULATORS THAT REGULATE TRANSCRIPTION OF TARGET GENES VIA DNA METHYLATION AND SITE-SPECIFIC HISTONE MODIFICATIONS. THIS MAY HAVE IMPLICATIONS IN DEVISING EPIGENETIC-BASED THERAPIES FOR COPD AND LUNG CANCER. 2016 2 1012 48 CIGARETTE SMOKE INDUCES DISTINCT HISTONE MODIFICATIONS IN LUNG CELLS: IMPLICATIONS FOR THE PATHOGENESIS OF COPD AND LUNG CANCER. CIGARETTE SMOKE (CS)-MEDIATED OXIDATIVE STRESS INDUCES SEVERAL SIGNALING CASCADES, INCLUDING KINASES, WHICH RESULTS IN CHROMATIN MODIFICATIONS (HISTONE ACETYLATION/DEACETYLATION AND HISTONE METHYLATION/DEMETHYLATION). WE HAVE PREVIOUSLY REPORTED THAT CS INDUCES CHROMATIN REMODELING IN PRO-INFLAMMATORY GENE PROMOTERS; HOWEVER, THE UNDERLYING SITE-SPECIFIC HISTONE MARKS FORMED IN HISTONES H3 AND H4 DURING CS EXPOSURE IN LUNGS IN VIVO AND IN LUNG CELLS IN VITRO, WHICH CAN EITHER DRIVE GENE EXPRESSION OR REPRESSION, ARE NOT KNOWN. WE HYPOTHESIZE THAT CS EXPOSURE IN MOUSE AND HUMAN BRONCHIAL EPITHELIAL CELLS (H292) CAN CAUSE SITE-SPECIFIC POSTTRANSLATIONAL HISTONE MODIFICATIONS (PTMS) THAT MAY PLAY AN IMPORTANT ROLE IN THE PATHOGENESIS OF CS-INDUCED CHRONIC LUNG DISEASES. WE USED A BOTTOM-UP MASS SPECTROMETRY APPROACH TO IDENTIFY SOME POTENTIALLY NOVEL HISTONE MARKS, INCLUDING ACETYLATION, MONOMETHYLATION, AND DIMETHYLATION, IN SPECIFIC LYSINE AND ARGININE RESIDUES OF HISTONES H3 AND H4 IN MOUSE LUNGS AND H292 CELLS. WE FOUND THAT CS-INDUCED DISTINCT POSTTRANSLATIONAL HISTONE MODIFICATION PATTERNS IN HISTONE H3 AND HISTONE H4 IN LUNG CELLS, WHICH MAY BE CONSIDERED AS USABLE BIOMARKERS FOR CS-INDUCED CHRONIC LUNG DISEASES. THESE IDENTIFIED HISTONE MARKS (HISTONE H3 AND HISTONE H4) MAY PLAY AN IMPORTANT ROLE IN THE EPIGENETIC STATE DURING THE PATHOGENESIS OF SMOKING-INDUCED CHRONIC LUNG DISEASES, SUCH AS CHRONIC OBSTRUCTIVE PULMONARY DISEASE AND LUNG CANCER. 2014 3 2493 45 EPIGENETICS AND CHROMATIN REMODELING PLAY A ROLE IN LUNG DISEASE. EPIGENETICS IS DEFINED AS HERITABLE CHANGES THAT AFFECT GENE EXPRESSION WITHOUT ALTERING THE DNA SEQUENCE. EPIGENETIC REGULATION OF GENE EXPRESSION IS FACILITATED THROUGH DIFFERENT MECHANISMS SUCH AS DNA METHYLATION, HISTONE MODIFICATIONS AND RNA-ASSOCIATED SILENCING BY SMALL NON-CODING RNAS. ALL THESE MECHANISMS ARE CRUCIAL FOR NORMAL DEVELOPMENT, DIFFERENTIATION AND TISSUE-SPECIFIC GENE EXPRESSION. THESE THREE SYSTEMS INTERACT AND STABILIZE ONE ANOTHER AND CAN INITIATE AND SUSTAIN EPIGENETIC SILENCING, THUS DETERMINING HERITABLE CHANGES IN GENE EXPRESSION. HISTONE ACETYLATION REGULATES DIVERSE CELLULAR FUNCTIONS INCLUDING INFLAMMATORY GENE EXPRESSION, DNA REPAIR AND CELL PROLIFERATION. TRANSCRIPTIONAL COACTIVATORS POSSESS INTRINSIC HISTONE ACETYLTRANSFERASE ACTIVITY AND THIS ACTIVITY DRIVES INFLAMMATORY GENE EXPRESSION. ELEVEN CLASSICAL HISTONE DEACETYLASES (HDACS) ACT TO REGULATE THE EXPRESSION OF DISTINCT SUBSETS OF INFLAMMATORY/IMMUNE GENES. THUS, LOSS OF HDAC ACTIVITY OR THE PRESENCE OF HDAC INHIBITORS CAN FURTHER ENHANCE INFLAMMATORY GENE EXPRESSION BY PRODUCING A GENE-SPECIFIC CHANGE IN HAT ACTIVITY. FOR EXAMPLE, HDAC2 EXPRESSION AND ACTIVITY ARE REDUCED IN LUNG MACROPHAGES, BIOPSY SPECIMENS, AND BLOOD CELLS FROM PATIENTS WITH SEVERE ASTHMA AND SMOKING ASTHMATICS, AS WELL AS IN PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). THIS MAY ACCOUNT, AT LEAST IN PART, FOR THE ENHANCED INFLAMMATION AND REDUCED STEROID RESPONSIVENESS SEEN IN THESE PATIENTS. OTHER PROTEINS, PARTICULARLY TRANSCRIPTION FACTORS, ARE ALSO ACETYLATED AND ARE TARGETS FOR DEACETYLATION BY HDACS AND SIRTUINS, A RELATED FAMILY OF 7 PREDOMINANTLY PROTEIN DEACETYLASES. THUS THE ACETYLATION/DEACETYLATION STATUS OF NF-KAPPAB AND THE GLUCOCORTICOID RECEPTOR CAN ALSO AFFECT THE OVERALL EXPRESSION PATTERN OF INFLAMMATORY GENES AND REGULATE THE INFLAMMATORY RESPONSE. UNDERSTANDING AND TARGETING SPECIFIC ENZYMES INVOLVED IN THIS PROCESS MIGHT LEAD TO NEW THERAPEUTIC AGENTS, PARTICULARLY IN SITUATIONS IN WHICH CURRENT ANTI-INFLAMMATORY THERAPIES ARE SUBOPTIMAL. 2011 4 6839 33 [LUNG CANCER AND ITS EPIGENETICS ASSOCIATION WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE]. LUNG CANCER AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) ARE THE LEADING CAUSES OF MORBIDITY AND MORTALITY WORLDWIDE. DEVELOPMENT OF LUNG CANCER INVOLVES BOTH GENETIC AND ENVIRONMENT FACTORS. IN ADDITION TO GENETIC ALTERATIONS, EPIGENETIC MECHANISM IS CLOSELY INVOLVED IN PATHOGENESIS OF LUNG CANCER. CHARACTERIZED BY AN ABNORMAL PERSISTENT INFLAMMATORY RESPONSE TO NOXIOUS ENVIRONMENTAL STIMULATION, COPD HAS SHOWN TO INCREASE THE SUSCEPTIBILITY FOR LUNG TUMORIGENESIS IN PREVIOUS RESEARCH. CURRENT RESEARCH ON EPIGENETICS OF LUNG CANCER AND COPD HAS FOCUSED ON ABERRANT DNA METHYLATION, HISTONE ACETYLATION AND NON-CODING RNAS REGULATION. THE ABERRANT DNA METHYLATION ASSOCIATED WITH LUNG CANCER AND COPD HAS INCLUDED OVEREXPRESSION OF DNA METHYLTRANSFERASE, GLOBAL DNA HYPOMETHYLATION AND DNA HYPERMETHYLATION IN PROMOTER REGIONS, WHILE HISTONE ACETYLATION AND HISTONE METHYLATION ARE THE MAJOR CHANGES FOR HISTONE MODIFICATION, IN WHICH HISTONE ACETYLTRANSFERASES, HISTONE DEACETYLASES, HISTONE METHYLTRANSFERASES AND HISTONE DEMETHYLASES PLAY THE MOST IMPORTANT ROLES. RNA INTERFERENCE AND MICRORNAS ARE BOTH HOT TOPICS OF RESEARCH ON NON-CODING RNAS REGULATION. UNDERSTANDING OF CONCURRENT EPIGENETIC ALTERATIONS IN THE PATHOGENESIS OF LUNG CANCER AND COPD MAY FACILITATE IDENTIFICATION OF SPECIFIC THERAPEUTIC TARGETS AND DEVELOPMENT OF EFFECTIVE TREATMENT. 2013 5 5418 47 REGULATION OF DNA METHYLATION SIGNATURES ON NF-KAPPAB AND STAT3 PATHWAY GENES AND TET ACTIVITY IN CIGARETTE SMOKE EXTRACT-CHALLENGED CELLS/COPD EXACERBATION MODEL IN VITRO. BACKGROUND: CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS A GLOBAL HEALTH PROBLEM. CURRENTLY, THERE IS A LACK OF KNOWLEDGE ABOUT THE PATHOBIOLOGY OF THIS DISEASE AND AVAILABLE THERAPIES ARE INEFFECTIVE. CIGARETTE SMOKING IS THE LEADING CAUSE OF COPD; HOWEVER, NOT ALL SMOKERS DEVELOP COPD. EXACERBATIONS OF COPD CAUSED BY MICROBES ARE COMMON AND DETRIMENTAL. APPROXIMATELY 20-50% OF PATIENT EXACERBATIONS ARE CAUSED BY BACTERIAL COLONIZATION IN THE LOWER AIRWAYS. IT IS GENERALLY ACCEPTED THAT EPIGENETIC MECHANISMS, ESPECIALLY DNA METHYLATION, PLAY AN IMPORTANT ROLE DURING PROGRESSION OF COPD. THUS, WE HYPOTHESIZED THAT DNA METHYLATION PATTERNS VARY SIGNIFICANTLY FOLLOWING SMOKE EXPOSURE AND DURING EXACERBATIONS CAUSED BY BACTERIAL INFECTIONS. TO TEST OUR HYPOTHESIS, WE USED AN IN VITRO STUDY MODEL THAT MIMICS COPD EXACERBATIONS AND PERFORMED EXTENSIVE STUDIES TO UNDERSTAND THE ROLE OF CPG PROMOTER METHYLATION OF NF-KAPPAB AND STAT3-MEDIATED PATHWAY GENES. BOTH NF-KAPPAB AND STAT3 TRANSCRIPTION FACTORS PLAY CRITICAL ROLES IN ORCHESTRATING INFLAMMATORY RESPONSES DURING CIGARETTE SMOKE EXPOSURE. IN BRIEF, HUMAN LUNG ADENOCARCINOMA CELLS WITH TYPE II ALVEOLAR EPITHELIUM CHARACTERISTICS (A549) WERE CHALLENGED WITH CIGARETTE SMOKE EXTRACT (CSE) OR DMSO (CONTROL) FOLLOWED BY A 3-H CHALLENGE WITH BACTERIAL LIPOPOLYSACCHARIDE (LPS; FROM PSEUDOMONAS AERUGINOSA) PRIOR TO THE TERMINATION OF CSE EXPOSURE (COPD EXACERBATION GROUP). THE PRODUCTION OF CYTOKINES/CHEMOKINES, REGULATION OF TRANSCRIPTION FACTORS, AND DNA METHYLATION OF SPECIFIC GENES WERE THEN ASSESSED. WE ALSO STUDIED CHANGES IN THE EXPRESSION AND ACTIVITY OF TEN-ELEVEN TRANSLOCASES (TETS), THE ENZYMES RESPONSIBLE FOR DNA DEMETHYLATION, AND ASSESSED THEIR ROLE IN REGULATING DNA METHYLATION IN THE CSE-CHALLENGED GROUP. RESULTS: THERE WAS A SIGNIFICANT INCREASE IN THE RELEASE OF CYTOKINES/CHEMOKINES (IL-8, MCP-1, IL-6 AND CCL5) IN THE COPD EXACERBATION GROUP AS COMPARED TO THE CONTROL GROUP. HYPOMETHYLATION OF NF-KAPPAB-MEDIATED PATHWAY GENES CORRELATED WITH THEIR INDUCTION IN OUR COPD EXACERBATION STUDY MODEL. FURTHER, WE OBSERVED AN IMPORTANT ROLE OF TET1/2 IN REGULATING THE DNA METHYLATION OF NF-KAPPAB, STAT3, IKK, AND NIK GENES AND CYTOKINE/CHEMOKINE PRODUCTION BY A549 CELLS DURING CSE CHALLENGE. CONCLUSIONS: STUDIES TO FURTHER DEFINE THE ROLE OF TETS IN CSE-MEDIATED EPIGENETIC REGULATION MAY LEAD TO THE DEVELOPMENT OF BETTER AND MORE EFFECTIVE THERAPEUTIC INTERVENTION STRATEGIES FOR COPD. 2020 6 1589 48 DNA METHYLATION PROFILING IN A CIGARETTE SMOKE-EXPOSED MOUSE MODEL OF AIRWAY INFLAMMATION. PURPOSE: DNA METHYLATION, A MAJOR EPIGENETIC MODIFICATION, HAS BEEN DOCUMENTED TO PLAY AN IMPORTANT ROLE IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). IN THIS STUDY, WE AIMED TO PROFILE THE DNA METHYLATION PATTERNS IN A MOUSE MODEL OF AIRWAY INFLAMMATION INDUCED BY CIGARETTE SMOKE (CS), A FOREMOST RISK FACTOR OF COPD. MATERIAL AND METHODS: TO ESTABLISH A MODEL OF AIRWAY INFLAMMATION, WILD-TYPE MICE WERE EXPOSED TO MAINSTREAM CS OR ROOM AIR FOR 2 HOURS TWICE DAILY, 6 DAYS PER WEEK FOR CONSECUTIVE 4 WEEKS. LUNG TISSUES OF THE MICE WERE COLLECTED FOR GENOME-WIDE DNA METHYLATION ANALYSIS BY LIQUID HYBRIDIZATION CAPTURE-BASED BISULFITE SEQUENCING, WHICH WERE USED FOR INTERSECTION ANALYSIS WITH GENE EXPRESSION BY CDNA MICROARRAY TO IDENTIFY CANDIDATE METHYLATED GENES. THEN, FUNCTIONAL ENRICHMENT ANALYSES WITH PROTEIN-PROTEIN INTERACTION (PPI) NETWORK REGARDING THESE GENES WERE CONDUCTED TO EXPLORE THE POTENTIAL MECHANISMS. RESULTS: AFTER 4-WEEK CS EXPOSURE, THE LEVEL OF DNA METHYLATION ACCOMPANIED BY A SUBACUTE AIRWAY INFLAMMATION WAS MARKEDLY ENHANCED, AND 2002 DIFFERENTIALLY METHYLATED GENES (DMGS) WERE ANNOTATED, INCLUDING 565 DMGS CONTAINED METHYLATIONS IN GENE PROMOTERS, WHICH WERE USED FOR INTERSECTION WITH THE DIFFERENTIALLY EXPRESSED GENES. THEN, 135 CANDIDATE METHYLATED GENES WERE FURTHER SELECTED BY THE INTERSECTION, AMONG WHICH 58 GENES WITH FUNCTIONAL METHYLATED MODIFICATION WERE FINALLY IDENTIFIED. FURTHER ANALYSES REVEALED CANDIDATE METHYLATED GENES WERE SIGNIFICANTLY ENRICHED IN A COMPLICATED NETWORK OF SIGNALS AND PROCESSES, INCLUDING INTERLEUKINS, TOLL-LIKE RECEPTORS, T-CELLS DIFFERENTIATION, OXIDATIVE STRESS, MAST CELLS ACTIVATION, STEM CELLS PROLIFERATION, ETC., AS WELL AS THE 58 FUNCTIONAL METHYLATED GENES WERE PARTIALLY LOCATED AT KEY POSITIONS IN PPI NETWORK, ESPECIALLY CXCL1, DDX58 AND JAK3. CONCLUSION: THIS STUDY SUGGESTS CS EXPOSURE SIGNIFICANTLY ENHANCES DNA METHYLATED LEVEL, AND THE POTENTIAL FUNCTIONAL METHYLATED GENES ARE CLOSELY RELATED TO COMPLICATED INFLAMMATORY-IMMUNE RESPONSES, WHICH MAY PROVIDE SOME NEW EXPERIMENTAL EVIDENCE IN UNDERSTANDING THE EPIGENETIC MECHANISMS OF CS-INDUCED AIRWAY INFLAMMATION IN COPD. 2022 7 4899 34 OXIDATIVE STRESS MEDIATES THE APOPTOSIS AND EPIGENETIC MODIFICATION OF THE BCL-2 PROMOTER VIA DNMT1 IN A CIGARETTE SMOKE-INDUCED EMPHYSEMA MODEL. BACKGROUND: EMPHYSEMA IS A CRUCIAL PATHOLOGICAL CHARACTERISTIC OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). OXIDATIVE STRESS, APOPTOSIS AND EPIGENETIC MECHANISMS CONTRIBUTE TO THE PATHOGENESIS OF EMPHYSEMA. HOWEVER, AN ATTEMPT TO ACCURATELY IDENTIFY WHETHER THESE MECHANISMS INTERACT WITH EACH OTHER AND HOW THEY ARE TRIGGERED HAS NEVER BEEN CONDUCTED. METHOD: THE TOTAL REACTIVE OXYGEN SPECIES (ROS) LEVEL, PULMONARY APOPTOSIS AND B-CELL LYMPHOMA/LEUKEMIA-2 (BCL-2) EXPRESSION, AN APOPTOSIS REGULATOR, WERE DETECTED IN SAMPLES FROM COPD PATIENTS. BISULFITE SEQUENCING PCR (BSP) WAS CONDUCTED TO OBSERVE THE ALTERATIONS IN THE METHYLATION OF THE BCL-2 PROMOTER IN SPECIMENS. THE DYSREGULATION OF DNA METHYLTRANSFERASE ENZYME 1 (DNMT1), A VITAL DNA METHYLTRANSFERASE ENZYME, IN THE LUNGS OF PATIENTS WAS CONFIRMED THROUGH WESTERN BLOTTING. TO FIND OUT INTERACTIONS BETWEEN OXIDATIVE STRESS AND DNA METHYLATION IN EMPHYSEMA, MOUSE MODELS WERE BUILT WITH ANTIOXIDANT TREATMENT AND DNMT1 SILENCING, AND WERE EXAMINED WITH THE PULMONARY APOPTOSIS, BCL-2 AND DNMT1 LEVELS, AND EPIGENETIC ALTERATIONS OF BCL-2. RESULTS: HIGHER ROS LEVELS AND PULMONARY APOPTOSIS WERE OBSERVED IN COPD PATIENTS THAN IN HEALTHY CONTROLS. DOWNREGULATED BCL-2 EXPRESSION WITH INCREASED PROMOTER METHYLATION AND DNMT1 PROTEIN EXPRESSION WAS FOUND IN COPD PATIENTS. ANTIOXIDANT TREATMENT REDUCED THE LEVEL OF ROS, DNMT1 PROTEIN AND EMPHYSEMATOUS PROGRESSION IN THE SMOKING MODELS. FOLLOWING DNMT1 BLOCKADE, SMOKING MODELS SHOWED IMPROVED LUNG FUNCTION, PULMONARY APOPTOSIS, EMPHYSEMATOUS PROGRESSION, AND INCREASED BCL-2 PROTEIN LEVEL WITH LESS PROMOTER METHYLATION THAN EMPHYSEMA MICE. CONCLUSION: CIGARETTE-INDUCED OXIDATIVE STRESS MEDIATES PULMONARY APOPTOSIS AND HYPERMETHYLATION OF THE BCL-2 PROMOTER IN EMPHYSEMA MODELS THROUGH DNMT1. 2020 8 1336 25 DESCRIBING A TRANSCRIPTION FACTOR DEPENDENT REGULATION OF THE MICRORNA TRANSCRIPTOME. WHILE THE TRANSCRIPTION REGULATION OF PROTEIN CODING GENES WAS EXTENSIVELY STUDIED, LITTLE IS KNOWN ON HOW TRANSCRIPTION FACTORS ARE INVOLVED IN TRANSCRIPTION OF NON-CODING RNAS, SPECIFICALLY OF MICRORNAS. HERE, WE PROPOSE A STRATEGY TO STUDY THE POTENTIAL ROLE OF TRANSCRIPTION FACTOR IN REGULATING TRANSCRIPTION OF MICRORNAS USING PUBLICALLY AVAILABLE DATA, COMPUTATIONAL RESOURCES AND HIGH THROUGHPUT DATA. WE USE THE H3K4ME3 EPIGENETIC SIGNATURE TO IDENTIFY MICRORNA PROMOTERS AND CHROMATIN IMMUNOPRECIPITATION (CHIP)-SEQUENCING DATA FROM THE ENCODE PROJECT TO IDENTIFY MICRORNA PROMOTERS THAT ARE ENRICHED WITH TRANSCRIPTION FACTOR BINDING SITES. BY TRANSFECTING CELLS OF INTEREST WITH SHRNA TARGETING A TRANSCRIPTION FACTOR OF INTEREST AND SUBJECTING THE CELLS TO MICRORNA ARRAY, WE STUDY THE EFFECT OF THIS TRANSCRIPTION FACTOR ON THE MICRORNA TRANSCRIPTOME. AS AN ILLUSTRATIVE EXAMPLE WE USE OUR STUDY ON THE EFFECT OF STAT3 ON THE MICRORNA TRANSCRIPTOME OF CHRONIC LYMPHOCYTIC LEUKEMIA (CLL) CELLS. 2016 9 5946 40 TARGETING THE EPIGENOME IN THE TREATMENT OF ASTHMA AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE. EPIGENETIC MODIFICATION OF GENE EXPRESSION BY METHYLATION OF DNA AND VARIOUS POST-TRANSLATIONAL MODIFICATIONS OF HISTONES MAY AFFECT THE EXPRESSION OF MULTIPLE INFLAMMATORY GENES. ACETYLATION OF HISTONES BY HISTONE ACETYLTRANSFERASES ACTIVATES INFLAMMATORY GENES, WHEREAS HISTONE DEACETYLATION RESULTS IN INFLAMMATORY GENE REPRESSION. CORTICOSTEROIDS EXERT THEIR ANTIINFLAMMATORY EFFECTS PARTLY BY INDUCING ACETYLATION OF ANTIINFLAMMATORY GENES, BUT MAINLY BY RECRUITING HISTONE DEACETYLASE-2 (HDAC2) TO ACTIVATED INFLAMMATORY GENES. HDAC2 DEACETYLATES ACETYLATED GLUCOCORTICOID RECEPTORS SO THAT THEY CAN SUPPRESS ACTIVATED INFLAMMATORY GENES IN ASTHMA. IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD), THERE IS RESISTANCE TO THE ANTIINFLAMMATORY ACTIONS OF CORTICOSTEROIDS, WHICH IS EXPLAINED BY REDUCED ACTIVITY AND EXPRESSION OF HDAC2. THIS CAN BE REVERSED BY A PLASMID VECTOR, WHICH RESTORES HDAC2 LEVELS, BUT MAY ALSO BE ACHIEVED BY LOW CONCENTRATIONS OF THEOPHYLLINE. OXIDATIVE STRESS CAUSES CORTICOSTEROID RESISTANCE BY REDUCING HDAC2 ACTIVITY AND EXPRESSION BY ACTIVATION OF PHOSPHOINOSITIDE-3-KINASE-DELTA, RESULTING IN HDAC2 PHOSPHORYLATION VIA A CASCADE OF KINASES. THEOPHYLLINE REVERSES CORTICOSTEROID RESISTANCE BY DIRECTLY INHIBITING OXIDANT-ACTIVATED PI3KDELTA AND IS MIMICKED BY PI3KDELTA KNOCKOUT OR BY SELECTIVE INHIBITORS. OTHER TREATMENTS MAY ALSO INTERACT IN THIS PATHWAY, MAKING IT POSSIBLE TO REVERSE CORTICOSTEROID RESISTANCE IN PATIENTS WITH COPD, AS WELL AS IN SMOKERS WITH ASTHMA AND SOME PATIENTS WITH SEVERE ASTHMA IN WHOM SIMILAR MECHANISMS OPERATE. OTHER HISTONE MODIFICATIONS, INCLUDING METHYLATION, TYROSINE NITRATION, AND UBIQUITINATION MAY ALSO AFFECT HISTONE FUNCTION AND INFLAMMATORY GENE EXPRESSION, AND BETTER UNDERSTANDING OF THESE EPIGENETIC PATHWAYS COULD LED TO NOVEL ANTIINFLAMMATORY THERAPIES, PARTICULARLY IN CORTICOSTEROID-RESISTANT INFLAMMATION. 2009 10 1251 38 CURRENT PERSPECTIVES ON ROLE OF CHROMATIN MODIFICATIONS AND DEACETYLASES IN LUNG INFLAMMATION IN COPD. CHROMATIN MODIFICATIONS AND EPIGENETIC REGULATION ARE CRITICAL FOR SUSTAINED AND ABNORMAL INFLAMMATORY RESPONSE SEEN IN LUNGS OF PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) BECAUSE THE ACTIVITIES OF ENZYMES THAT REGULATE THESE EPIGENETIC MODIFICATIONS ARE ALTERED IN RESPONSE TO CIGARETTE SMOKE. CIGARETTE SMOKE INDUCES CHROMATIN MODIFICATIONS AND EPIGENETIC CHANGES BY CAUSING POST-TRANSLATIONAL MODIFICATIONS OF HISTONE ACETYLTRANSFERASES, AND HISTONE/NON-HISTONE DEACETYLASES (HDACS), SUCH AS HDAC2 AND SIRTUIN 1 (SIRT1), WHICH LEADS TO CHROMATIN REMODELING. IN THIS REVIEW, WE DISCUSSED THE CURRENT KNOWLEDGE ON CIGARETTE SMOKE/OXIDANTS-INDUCED POST-TRANSLATIONAL MODIFICATIONS OF DEACETYLASES (HDAC2 AND SIRT1), DISRUPTION OF HDAC2/SIRT1-RELA/P65 COREPRESSOR COMPLEX ASSOCIATED WITH ACETYLATION OF RELA/P65, AND CHROMATIN MODIFICATIONS (HISTONE H3 PHOSPHO-ACETYLATION) LEADING TO SUSTAINED PRO-INFLAMMATORY GENE TRANSCRIPTION. KNOWLEDGE ON MOLECULAR MECHANISMS OF EPIGENETIC CHANGES IN ABNORMAL LUNG INFLAMMATION WILL HELP IN UNDERSTANDING THE PATHOPHYSIOLOGY OF COPD WHICH MAY LEAD TO THE DEVELOPMENT OF NOVEL EPIGENETIC THERAPIES IN THE NEAR FUTURE. 2009 11 1551 42 DNA METHYLATION IS GLOBALLY DISRUPTED AND ASSOCIATED WITH EXPRESSION CHANGES IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE SMALL AIRWAYS. DNA METHYLATION IS AN EPIGENETIC MODIFICATION THAT IS HIGHLY DISRUPTED IN RESPONSE TO CIGARETTE SMOKE AND INVOLVED IN A WIDE SPECTRUM OF MALIGNANT AND NONMALIGNANT DISEASES, BUT SURPRISINGLY NOT PREVIOUSLY ASSESSED IN SMALL AIRWAYS OF PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). SMALL AIRWAYS ARE THE PRIMARY SITES OF AIRFLOW OBSTRUCTION IN COPD. WE SOUGHT TO DETERMINE WHETHER DNA METHYLATION PATTERNS ARE DISRUPTED IN SMALL AIRWAY EPITHELIA OF PATIENTS WITH COPD, AND EVALUATE WHETHER CHANGES IN GENE EXPRESSION ARE ASSOCIATED WITH THESE DISRUPTIONS. GENOME-WIDE METHYLATION AND GENE EXPRESSION ANALYSIS WERE PERFORMED ON SMALL AIRWAY EPITHELIAL DNA AND RNA OBTAINED FROM THE SAME PATIENT DURING BRONCHOSCOPY, USING ILLUMINA'S INFINIUM HM27 AND AFFYMETRIX'S GENECHIP HUMAN GENE 1.0 ST ARRAYS. TO CONTROL FOR KNOWN EFFECTS OF CIGARETTE SMOKING ON DNA METHYLATION, METHYLATION AND GENE EXPRESSION PROFILES WERE COMPARED BETWEEN FORMER SMOKERS WITH AND WITHOUT COPD MATCHED FOR AGE, PACK-YEARS, AND YEARS OF SMOKING CESSATION. OUR RESULTS INDICATE THAT ABERRANT DNA METHYLATION IS (1) A GENOME-WIDE PHENOMENON IN SMALL AIRWAYS OF PATIENTS WITH COPD, AND (2) ASSOCIATED WITH ALTERED EXPRESSION OF GENES AND PATHWAYS IMPORTANT TO COPD, SUCH AS THE NF-E2-RELATED FACTOR 2 OXIDATIVE RESPONSE PATHWAY. DNA METHYLATION IS LIKELY AN IMPORTANT MECHANISM CONTRIBUTING TO MODULATION OF GENES IMPORTANT TO COPD PATHOLOGY. BECAUSE THESE METHYLATION EVENTS MAY UNDERLIE DISEASE-SPECIFIC GENE EXPRESSION CHANGES, THEIR CHARACTERIZATION IS A CRITICAL FIRST STEP TOWARD THE DEVELOPMENT OF EPIGENETIC MARKERS AND AN OPPORTUNITY FOR DEVELOPING NOVEL EPIGENETIC THERAPEUTIC INTERVENTIONS FOR COPD. 2014 12 4889 48 OXIDATIVE STRESS AND CHROMATIN REMODELING IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE AND SMOKING-RELATED DISEASES. SIGNIFICANCE: CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS PREDOMINANTLY A TOBACCO SMOKE-TRIGGERED DISEASE WITH FEATURES OF CHRONIC LOW-GRADE SYSTEMIC INFLAMMATION AND AGING (INFLAMMAGING) OF THE LUNG ASSOCIATED WITH STEROID RESISTANCE INDUCED BY CIGARETTE SMOKE (CS)-MEDIATED OXIDATIVE STRESS. OXIDATIVE STRESS INDUCES VARIOUS KINASE SIGNALING PATHWAYS LEADING TO CHROMATIN MODIFICATIONS (HISTONE ACETYLATION/DEACETYLATION AND HISTONE METHYLATION/DEMETHYLATION) IN INFLAMMATION, SENESCENCE, AND STEROID RESISTANCE. RECENT ADVANCES: HISTONE MONO-, DI-, OR TRI-METHYLATION AT LYSINE RESIDUES RESULT IN EITHER GENE ACTIVATION (H3K4, H3K36, AND H3K79) OR REPRESSION (H3K9, H3K27, AND H3K20). CROSS-TALK OCCURS BETWEEN VARIOUS EPIGENETIC MARKS ON HISTONES AND DNA METHYLATION. BOTH CS AND OXIDANTS ALTER HISTONE ACETYLATION/DEACETYLATION AND METHYLATION/DEMETHYLATION LEADING TO ENHANCED PROINFLAMMATORY GENE EXPRESSION. CHROMATIN MODIFICATIONS OCCUR IN LUNGS OF PATIENTS WITH COPD. HISTONE DEACETYLASE 2 (HDAC2) REDUCTION (LEVELS AND ACTIVITY) IS ASSOCIATED WITH STEROID RESISTANCE IN RESPONSE TO OXIDATIVE STRESS. CRITICAL ISSUES: HISTONE MODIFICATIONS ARE ASSOCIATED WITH DNA DAMAGE/REPAIR AND EPIGENOMIC INSTABILITY AS WELL AS PREMATURE LUNG AGING, WHICH HAVE IMPLICATIONS IN THE PATHOGENESIS OF COPD. HDAC2/SIRTUIN1 (SIRT1)-DEPENDENT CHROMATIN MODIFICATIONS ARE ASSOCIATED WITH DNA DAMAGE-INDUCED INFLAMMATION AND SENESCENCE IN RESPONSE TO CS-MEDIATED OXIDATIVE STRESS. FUTURE DIRECTIONS: UNDERSTANDING CS/OXIDATIVE STRESS-MEDIATED CHROMATIN MODIFICATIONS AND THE CROSS-TALK BETWEEN HISTONE ACETYLATION AND METHYLATION WILL DEMONSTRATE THE INVOLVEMENT OF EPIGENETIC REGULATION OF CHROMATIN REMODELING IN INFLAMMAGING. THIS WILL LEAD TO IDENTIFICATION OF NOVEL EPIGENETIC-BASED THERAPIES AGAINST COPD AND OTHER SMOKING-RELATED LUNG DISEASES. PHARMACOLOGICAL ACTIVATION OF HDAC2/SIRT1 OR REVERSAL OF THEIR OXIDATIVE POST-TRANSLATIONAL MODIFICATIONS MAY OFFER THERAPIES FOR TREATMENT OF COPD AND CS-RELATED DISEASES BASED ON EPIGENETIC HISTONE MODIFICATIONS. 2013 13 3767 45 INTEGRATIVE EPIGENOMIC ANALYSIS IN DIFFERENTIATED HUMAN PRIMARY BRONCHIAL EPITHELIAL CELLS EXPOSED TO CIGARETTE SMOKE. CIGARETTE SMOKE (CS) IS ONE OF THE MAJOR RISK FACTORS FOR MANY PULMONARY DISEASES, INCLUDING CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) AND LUNG CANCER. THE FIRST LINE OF DEFENSE FOR CS EXPOSURE IS THE BRONCHIAL EPITHELIAL CELLS. ELUCIDATION OF THE EPIGENETIC CHANGES DURING CS EXPOSURE IS KEY TO GAINING A MECHANISTIC UNDERSTANDING INTO HOW MATURE AND DIFFERENTIATED BRONCHIAL EPITHELIAL CELLS RESPOND TO CS. THEREFORE, WE PERFORMED EPIGENOMIC PROFILING IN CONJUNCTION WITH TRANSCRIPTIONAL PROFILING IN WELL-DIFFERENTIATED HUMAN BRONCHIAL EPITHELIAL (HBE) CELLS CULTURED IN AIR-LIQUID INTERFACE (ALI) EXPOSED TO THE VAPOR PHASE OF CS. THE GENOME-WIDE ENRICHMENT OF HISTONE 3 LYSINE 27 ACETYLATION WAS DETECTED BY CHROMATIN IMMUNOPRECIPITATION FOLLOWED BY NEXT GENERATION SEQUENCING (CHIP-SEQ) IN HBE CELLS AND SUGGESTED THE PLAUSIBLE BINDING OF SPECIFIC TRANSCRIPTION FACTORS RELATED TO CS EXPOSURE. ADDITIONALLY, INTERROGATION OF CHIP-SEQ DATA WITH GENE EXPRESSION PROFILING OF HBE CELLS AFTER CS EXPOSURE FOR DIFFERENT DURATIONS (3 HOURS, 2 DAYS, 4 DAYS) SUGGESTED THAT EARLIER EPIGENETIC CHANGES (3 HOURS AFTER CS EXPOSURE) MAY BE ASSOCIATED WITH LATER GENE EXPRESSION CHANGES INDUCED BY CS EXPOSURE (4 DAYS). THE INTEGRATION OF EPIGENETICS AND GENE EXPRESSION DATA REVEALED SIGNALING PATHWAYS RELATED TO CS-INDUCED EPIGENETIC CHANGES IN HBE CELLS THAT MAY IDENTIFY NOVEL REGULATORY PATHWAYS RELATED TO CS-INDUCED COPD. 2018 14 141 35 ABERRANT DNA METHYLATION OF MTOR PATHWAY GENES PROMOTES INFLAMMATORY ACTIVATION OF IMMUNE CELLS IN DIABETIC KIDNEY DISEASE. DNA METHYLATION HAS BEEN IMPLICATED IN THE PATHOGENESIS OF DIABETIC KIDNEY DISEASE (DKD), BUT THE UNDERLYING MECHANISMS REMAIN UNCLEAR. IN THIS STUDY, WE TESTED THE HYPOTHESIS THAT ABERRANT DNA METHYLATION IN PERIPHERAL IMMUNE CELLS CONTRIBUTES TO DKD PROGRESSION. WE SHOWED THAT LEVELS OF DNA METHYLTRANSFERASE 1 (DNMT1), A KEY ENZYME FOR DNA METHYLATION, WERE INCREASED ALONG WITH INFLAMMATORY ACTIVITY OF PERIPHERAL BLOOD MONONUCLEAR CELLS IN DKD PATIENTS. INHIBITION OF DNMT1 WITH 5-AZA-2'-DEOXYCYTIDINE (5-AZA) MARKEDLY INCREASED THE PROPORTION OF CD4(+)CD25(+) REGULATORY T CELLS IN PERIPHERAL BLOOD MONONUCLEAR CELLS IN CULTURE AND IN DIABETIC ANIMALS. ADOPTIVE TRANSFER OF IMMUNE CELLS FROM 5-AZA-TREATED ANIMALS SHOWED BENEFICIAL EFFECTS ON THE HOST IMMUNE SYSTEM, RESULTING IN A SIGNIFICANT IMPROVEMENT OF DKD. USING GENOME-WIDE DNA METHYLATION ASSAYS, WE IDENTIFIED THE DIFFERENTIALLY METHYLATED CYTOSINES IN THE PROMOTER REGIONS OF MAMMALIAN TARGET OF RAPAMYCIN (MTOR) REGULATORS IN PERIPHERAL BLOOD MONONUCLEAR CELLS OF DIABETIC PATIENTS. FURTHER, MRNA ARRAYS CONFIRMED THE CONSISTENT INDUCTION OF GENES EXPRESSED IN THE MTOR PATHWAY. IMPORTANTLY, DOWN-REGULATION OF DNMT1 EXPRESSION VIA RNA INTERFERENCE RESULTED IN PROMINENT CYTOSINE DEMETHYLATION OF MTOR NEGATIVE REGULATORS AND SUBSEQUENT DECREASE OF MTOR ACTIVITY. LASTLY, MODULATION OF MTOR RESULTED IN CHANGES IN THE EFFECT OF 5-AZA ON DIABETIC IMMUNE CELLS. THUS, UP-REGULATION OF DNMT1 IN DIABETIC IMMUNE CELLS INDUCES ABERRANT CYTOSINE METHYLATION OF THE UPSTREAM REGULATORS OF MTOR, LEADING TO PATHOGENIC ACTIVATION OF THE MTOR PATHWAY AND CONSEQUENT INFLAMMATION IN DIABETIC KIDNEYS. HENCE, THIS STUDY HIGHLIGHTS THERAPEUTIC POTENTIAL OF TARGETING EPIGENETIC EVENTS IN IMMUNE SYSTEM FOR TREATING DKD. 2019 15 5067 35 PHYSICAL ACTIVITY AND DNA METHYLATION IN HUMANS. PHYSICAL ACTIVITY IS A STRONG STIMULUS INFLUENCING THE OVERALL PHYSIOLOGY OF THE HUMAN BODY. EXERCISES LEAD TO BIOCHEMICAL CHANGES IN VARIOUS TISSUES AND EXERT AN IMPACT ON GENE EXPRESSION. EXERCISE-INDUCED CHANGES IN GENE EXPRESSION MAY BE MEDIATED BY EPIGENETIC MODIFICATIONS, WHICH REARRANGE THE CHROMATIN STRUCTURE AND THEREFORE MODULATE ITS ACCESSIBILITY FOR TRANSCRIPTION FACTORS. ONE OF SUCH EPIGENETIC MARK IS DNA METHYLATION THAT INVOLVES AN ATTACHMENT OF A METHYL GROUP TO THE FIFTH CARBON OF CYTOSINE RESIDUE PRESENT IN CG DINUCLEOTIDES (CPG). DNA METHYLATION IS CATALYZED BY A FAMILY OF DNA METHYLTRANSFERASES. THIS REVERSIBLE DNA MODIFICATION RESULTS IN THE RECRUITMENT OF PROTEINS CONTAINING METHYL BINDING DOMAIN AND FURTHER TRANSCRIPTIONAL CO-REPRESSORS LEADING TO THE SILENCING OF GENE EXPRESSION. THE ACCUMULATION OF CPG DINUCLEOTIDES, REFERRED AS CPG ISLANDS, OCCURS AT THE PROMOTER REGIONS IN A GREAT MAJORITY OF HUMAN GENES. THEREFORE, CHANGES IN DNA METHYLATION PROFILE AFFECT THE TRANSCRIPTION OF MULTIPLE GENES. A GROWING BODY OF EVIDENCE INDICATES THAT EXERCISE TRAINING MODULATES DNA METHYLATION IN MUSCLES AND ADIPOSE TISSUE. SOME OF THESE EPIGENETIC MARKERS WERE ASSOCIATED WITH A REDUCED RISK OF CHRONIC DISEASES. THIS REVIEW SUMMARIZES THE CURRENT KNOWLEDGE ABOUT THE INFLUENCE OF PHYSICAL ACTIVITY ON THE DNA METHYLATION STATUS IN HUMANS. 2021 16 5279 30 PROMOTER-SPECIFIC RELEVANCE OF HISTONE MODIFICATIONS INDUCED BY DEXAMETHASONE DURING THE REGULATION OF PRO-INFLAMMATORY MEDIATORS. GLUCOCORTICOSTEROIDS (GCS) ARE WIDELY USED TO TREAT DIFFERENT KINDS OF CHRONIC INFLAMMATORY AND IMMUNE DISEASES THROUGH TRANSCRIPTIONAL REGULATION OF INFLAMMATORY GENES. MODULATION OF GENE EXPRESSION BY GCS IS KNOWN TO OCCUR THROUGH DIVERSE MECHANISMS OF VARYING RELEVANCE TO SPECIFIC CLASSES OF GENES. EPIGENETIC MODIFICATIONS ARE INDEED A PIVOTAL REGULATORY FEATURE OF GLUCOCORTICOID RECEPTOR AND OTHER TRANSCRIPTION FACTORS. IN THIS STUDY, HISTONE POST-TRANSLATIONAL MODIFICATIONS WERE INVESTIGATED FOR THEIR INVOLVEMENT IN THE REGULATION OF SELECTED PRO-INFLAMMATORY GENES - EXPRESSED IN HUMAN MONOCYTE-DERIVED MACROPHAGES - IN RESPONSE TO TREATMENT WITH SYNTHETIC GC DEXAMETHASONE (DEX). WE SHOW THAT HISTONE TAIL ACETYLATION STATUS IS MODIFIED FOLLOWING DEX ADMINISTRATION, THROUGH DISTINCT AND ALTERNATIVE MECHANISMS AT THE PROMOTERS OF INTERLEUKIN-8 AND INTERLEUKIN-23. IN ADDITION TO HISTONE H3 ACETYLATION, OUR RESULTS DEMONSTRATE THAT H3 LYSINE 4 TRIMETHYLATION IS AFFECTED FOLLOWING DRUG TREATMENT. 2014 17 4302 44 MICRORNA-223 CONTROLS THE EXPRESSION OF HISTONE DEACETYLASE 2: A NOVEL AXIS IN COPD. REDUCED ACTIVITY OF HISTONE DEACETYLASE 2 (HDAC2) HAS BEEN DESCRIBED IN PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD), BUT THE MECHANISMS RESULTING IN DECREASED EXPRESSION OF THIS IMPORTANT EPIGENETIC MODIFIER REMAIN UNKNOWN. HERE, WE EMPLOYED SEVERAL IN VITRO EXPERIMENTS TO ADDRESS THE ROLE OF MICRORNAS (MIRNAS) ON THE REGULATION OF HDAC2 IN ENDOTHELIAL CELLS. MANIPULATION OF MIRNA LEVELS IN HUMAN PULMONARY ARTERY ENDOTHELIAL CELLS (HPAEC) WAS ACHIEVED BY USING ELECTROPORATION WITH ANTI-MIRNAS AND MIRNA MIMICS. TARGET PREDICTION SOFTWARE IDENTIFIED MIR-223 AS A POTENTIAL REPRESSOR OF HDAC2. IN SUBSEQUENT STIMULATION EXPERIMENTS USING INFLAMMATORY CYTOKINES KNOWN TO BE INCREASED IN PATIENTS WITH COPD, MIR-223 WAS FOUND TO BE SIGNIFICANTLY INDUCED. FUNCTIONAL ANALYSIS DEMONSTRATED THAT OVEREXPRESSION OF MIR-223 DECREASED HDAC2 EXPRESSION AND ACTIVITY IN HPAEC. CONVERSELY, HDAC2 EXPRESSION AND ACTIVITY WAS PRESERVED IN ANTI-MIR-223-TREATED CELLS. DIRECT MIRNA-TARGET INTERACTION WAS CONFIRMED BY REPORTER GENE ASSAY. IN A NEXT STEP, REDUCED EXPRESSION OF HDAC2 WAS FOUND TO INCREASE THE LEVELS OF THE CHEMOKINE FRACTALKINE (CX3CL1). IN VIVO STUDIES CONFIRMED ELEVATED EXPRESSION LEVELS OF MIR-223 IN MICE EXPOSED TO CIGARETTE SMOKE AND IN EMPHYSEMATOUS LUNG TISSUE FROM LPS-TREATED MICE. MOREOVER, A SIGNIFICANT INVERSE CORRELATION OF MIR-223 AND HDAC2 EXPRESSION WAS FOUND IN TWO INDEPENDENT COHORTS OF COPD PATIENTS. THESE DATA EMPHASIZE THAT MIR-223, THE MOST PREVALENT MIRNA IN COPD, CONTROLS EXPRESSION AND ACTIVITY OF HDAC2 IN PULMONARY CELLS, WHICH, IN TURN, MIGHT ALTER THE EXPRESSION PROFILE OF CHEMOKINES. THIS PATHWAY PROVIDES A NOVEL PATHOGENIC LINK BETWEEN DYSREGULATED MIRNA EXPRESSION AND EPIGENETIC ACTIVITY IN COPD. KEY MESSAGES: HISTONE DEACETYLASE 2 IS DIRECTLY TARGETED BY MIR-223. LEVELS OF MIR-223 ARE INDUCED BY INTERLEUKIN-1BETA AND TUMOR NECROSIS FACTOR-ALPHA. MIR-223 CONTROLS THE EXPRESSION OF FRACTALKINE BY TARGETING HISTONE DEACETYLASE 2. MIR-223 LEVELS ARE INCREASED IN COPD MOUSE MODELS. MIR-223 LEVELS INVERSELY CORRELATE WITH HDAC2 EXPRESSION IN COPD PATIENTS. 2016 18 2161 36 EPIGENETIC MECHANISMS IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE. EPIGENETIC MODIFICATION MAY AFFECT THE EXPRESSION OF MULTIPLE INFLAMMATORY GENES IN LUNGS OF PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). MAJOR EPIGENETIC EVENTS INCLUDE DNA METHYLATION AND VARIOUS POST-TRANSLATIONAL MODIFICATIONS OF HISTONES, SUCH AS HISTONE METHYLATION, ACETYLATION, PHOSPHORYLATION, UBIQUITINATION, AND SUMOYLATION. ENZYMES WHICH REGULATE THESE EPIGENETIC MODIFICATIONS CAN BE ACTIVATED BY SMOKING. BOTH ENVIRONMENTAL AND GENETIC FACTORS PLAY SIGNIFICANT EFFECT IN DEVELOPMENT OF COPD WHICH HAVE BEEN REPORTED BY MOST REFERENCES; HOWEVER, LITTLE IS KNOWN ABOUT THE EPIGENETIC PATHWAYS INVOLVED IN THE DISEASE. UNDERSTANDING THE EPIGENETIC MECHANISMS CAN HELP US CLARIFY THE PATHOGENESIS OF COPD AND IDENTIFY NOVEL TARGETS FOR DEVELOPING NEW THERAPIES FOR PATIENTS WITH COPD. 2015 19 3831 46 INVOLVEMENT OF INFLAMMATORY CYTOKINES AND EPIGENETIC MODIFICATION OF THE MTTFA COMPLEX IN T-HELPER CELLS OF PATIENTS' SUFFERING FROM NON-SMALL CELL LUNG CANCER AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE. DYSREGULATED INFLAMMATORY RESPONSE PLAYS A CRUCIAL ROLE IN THE PATHOGENESIS OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) AND NON-SMALL CELL LUNG CANCER (NSCLC). HENCE, THE PURPOSE OF THIS RESEARCH IS TO UNCOVER THE LINK BETWEEN ALTERATIONS IN INFLAMMATORY CYTOKINE LEVELS AND DISEASE PROGRESSION IN CD4(+)T CELLS OF PATIENTS SUFFERING FROM COPD AND LUNG CANCER. WE ALSO INVESTIGATED THE EPIGENETIC REGULATION OF MTTFA TO DELINEATE THE ROLE OF OXIDATIVE STRESS-MEDIATED INFLAMMATION IN LUNG CANCER AND COPD. THE RT(2) PROFILER PCR ARRAY WAS USED TO EXAMINE THE DIFFERENTIAL EXPRESSION PATTERN OF INFLAMMATORY GENES IN CD4(+) T HELPER (TH) CELLS FROM COPD, NSCLC, AND CONTROL SUBJECTS. CANDIDATE INFLAMMATORY GENE LOCI WERE SELECTED AND THE ENRICHMENT OF TRANSCRIPTIONAL FACTOR AND HISTONE MODIFIERS WAS ANALYSED USING CHIP-QPCR. IN COMPARISON TO CONTROL SUBJECTS, A SET OF GENES (E.G., BMP2, CCL2, IL5, VEGFA, ETC.) ARE OVER-EXPRESSED WHEREAS ANOTHER SET OF GENES (E.G., AIMP1, IFNG, LTA, LTB, TNF, ETC.) ARE UNDER-EXPRESSED IN BOTH COPD AND NSCLC PATIENTS. THE INCREASED PERCENT ENRICHMENT OF INFLAMMATION-ASSOCIATED TRANSCRIPTION FACTORS INCLUDING NF-KB, CREB, HIF1, AND MYC AT THE LOCI OF INFLAMMATORY GENES WAS REVEALED BY OUR CHROMATIN IMMUNOPRECIPITATION (CHIP) DATA. H3K4ME3, H3K9ME3, H3K14AC, HDAC1, 2, 3, 6 ALL SHOWED DYSREGULATED ENRICHMENT AT THE VEGFA GENE LOCUS. ONE OF THE EPIGENETIC MODIFICATIONS, HISTONE METHYLATION, WAS FOUND TO BE ABNORMAL IN THE MTTFA COMPLEX IN COPD AND NSCLC PATIENTS IN COMPARISON TO CONTROLS. ALTHOUGH THERE IS MOUNTING EVIDENCE OF SEVERAL LINKS BETWEEN THESE DISORDERS, THERAPEUTIC OPTIONS REMAIN INADEQUATE. OUR FINDINGS CONTRIBUTE TO THE BODY OF KNOWLEDGE ABOUT THERAPEUTIC TECHNIQUES THAT USE INFLAMMATORY CYTOKINES AS A PROGNOSTIC MARKER AND HIGHLIGHT THE NEED FOR EPIGENETIC THERAPY FOR THESE DEBILITATING LUNG DISEASES. 2022 20 1731 38 DYSREGULATION OF THE HISTONE DEMETHYLASE KDM6B IN ALCOHOL DEPENDENCE IS ASSOCIATED WITH EPIGENETIC REGULATION OF INFLAMMATORY SIGNALING PATHWAYS. EPIGENETIC ENZYMES OVERSEE LONG-TERM CHANGES IN GENE EXPRESSION BY INTEGRATING GENETIC AND ENVIRONMENTAL CUES. WHILE THERE ARE HUNDREDS OF ENZYMES THAT CONTROL HISTONE AND DNA MODIFICATIONS, THEIR POTENTIAL ROLES IN SUBSTANCE ABUSE AND ALCOHOL DEPENDENCE REMAIN UNDEREXPLORED. A FEW RECENT STUDIES HAVE SUGGESTED THAT EPIGENETIC PROCESSES COULD UNDERLIE TRANSCRIPTOMIC AND BEHAVIORAL HALLMARKS OF ALCOHOL ADDICTION. IN THE PRESENT STUDY, WE SOUGHT TO IDENTIFY EPIGENETIC ENZYMES IN THE BRAIN THAT ARE DYSREGULATED DURING PROTRACTED ABSTINENCE AS A CONSEQUENCE OF CHRONIC AND INTERMITTENT ALCOHOL EXPOSURE. THROUGH QUANTITATIVE MRNA EXPRESSION ANALYSIS OF OVER 100 EPIGENETIC ENZYMES, WE IDENTIFIED 11 THAT ARE SIGNIFICANTLY ALTERED IN ALCOHOL-DEPENDENT RATS COMPARED WITH CONTROLS. FOLLOW-UP STUDIES OF ONE OF THESE ENZYMES, THE HISTONE DEMETHYLASE KDM6B, SHOWED THAT THIS ENZYME EXHIBITS REGION-SPECIFIC DYSREGULATION IN THE PREFRONTAL CORTEX AND NUCLEUS ACCUMBENS OF ALCOHOL-DEPENDENT RATS. KDM6B WAS ALSO UPREGULATED IN THE HUMAN ALCOHOLIC BRAIN. UPREGULATION OF KDM6B PROTEIN IN ALCOHOL-DEPENDENT RATS WAS ACCOMPANIED BY A DECREASE OF TRIMETHYLATION LEVELS AT HISTONE H3, LYSINE 27 (H3K27ME3), CONSISTENT WITH THE KNOWN DEMETHYLASE SPECIFICITY OF KDM6B. SUBSEQUENT EPIGENETIC (CHROMATIN IMMUNOPRECIPITATION [CHIP]-SEQUENCING) ANALYSIS SHOWED THAT ALCOHOL-INDUCED CHANGES IN H3K27ME3 WERE SIGNIFICANTLY ENRICHED AT GENES IN THE IL-6 SIGNALING PATHWAY, CONSISTENT WITH THE WELL-CHARACTERIZED ROLE OF KDM6B IN MODULATION OF INFLAMMATORY RESPONSES. KNOCKDOWN OF KDM6B IN CULTURED MICROGLIAL CELLS DIMINISHED IL-6 INDUCTION IN RESPONSE TO AN INFLAMMATORY STIMULUS. OUR FINDINGS IMPLICATE A NOVEL KDM6B-MEDIATED EPIGENETIC SIGNALING PATHWAY INTEGRATED WITH INFLAMMATORY SIGNALING PATHWAYS THAT ARE KNOWN TO UNDERLIE THE DEVELOPMENT OF ALCOHOL ADDICTION. 2021